创伤性脑损伤人体头部剪切冲击波的模拟

B. Tripathi, G. Pinton
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引用次数: 0

摘要

我们最近在实验中观察到,从较低的初始加速度(次震荡范围)开始,在大脑深处产生剪切冲击波。这一观察结果推动了模拟工具的发展,以模拟人类头部的剪切冲击波。目前描述非线性横波传播的数值方法是在延迟时间内进行的,这使得它们是单向的,并且它们只对小角度有效。一个全波模型可以捕捉到在创伤事件中发生的更大范围的冲击波物理现象。在这里,我们提出了:1)一个非线性的守恒定律系统,该系统模拟了线性偏振剪切波在二维中的传播,2)一个使用松弛机制的软固体中的衰减/色散模型,3)使用分段抛物法(PPM)对(1)-(2)进行了数值模拟。该系统采用非分裂和保守的PPM实现,具有局部拉克斯-弗里德里希通量,加上时间上的二阶分裂。2D m…
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simulation of shear shock waves in the human head for traumatic brain injury
We have recently observed, experimentally, that shear shock waves are generated deep inside the brain starting from a low initial acceleration (sub-concussive range). This observation has motivated the development of simulation tools to model shear shock waves in the human head. Current numerical methods that describe nonlinear shear wave propagation are in retarded time which makes them unidirectional, and they are valid for small angles only. A full-wave model would capture a much wider range of shock wave physics that occurs during a traumatic event. Here we present: 1) a nonlinear system of conservation laws that models the propagation of linearly-polarized shear waves in 2D, 2) a model of the attenuation/dispersion in soft solids using relaxation mechanisms, 3) numerical simulations of (1)-(2) using the Piecewise Parabolic Method (PPM). This system is solved using an un-split and conservative implementation of PPM with a local Lax-Friedrichs flux, coupled with second-order splitting in time. The 2D m...
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